Reproduction of <i>Meloidogyne morocciensis</i> (Tylenchida: Meloidogynidae) in weeds found in Brazil

KASPARY, TIAGO EDU; RAMOS, RODRIGO F.; SOBUCKI, LISIANE; BALARDIN, RICARDO R.; NORA, DAIANE DALLA; BELLÉ, CRISTIANO

doi:10.1590/0001-3765202320190377

Abstract

Weeds can be hosts of root-knot nematodes of the genus Meloidogyne. The importance of the species Meloidogyne morocciensis parasitizing many crops is recognized, but their reproductive capacity in weeds is not known. The present study hypothesizes the ability of M. morocciensis to parasitize and reproduce in different weed species found in Brazil. The objective was to evaluate the reproduction of M. morocciensis in 36 weed species. The plants were individually inoculated with 5,000 eggs and second stage juveniles and kept in greenhouse for 60 days. The experimental design was completely randomized with twelve replications. The root system of each plant was evaluated for gall index (GI), final nematode population (PF), number of nematode/g of root (NNGR) and reproduction factor (RF). It was verified that M. morocciensis has the capacity to parasite 36 weed species belonging to 16 different botanical families, confirming the hypothesis proposed. From the 36 species evaluated, 77.8% (28) were susceptible (FR ≥ 1.0) to M. morocciensis. The present study is the first to identify different weeds as hosts of M. morocciensis, evidencing its polyphagous habit, indicating species of plants with high capacity to multiply this nematode and that need more attention during the integrated management of these pathogen.

Key words
invasive plants; host status; nematode reproduction; root-knot nematodes

INTRODUCTION

Weeds are one of the most important biotic factors limiting agricultural crops. The damage caused to crop development and productivity can be generated by direct competition for resources such as water, light and nutrients, or by the action of allelopathic compounds produced by weeds (Fried et al. 2017FRIED G, CHAUVEL B, REYNAUD P & SACHE I. 2017. Decreases in Crop Production by Non-native Weeds, Pests, and Pathogens. In: Impact of Biological Invasions on Ecosystem Services, 12. Invading Nature - Springer Series in Invasion Ecology, vol 12. Springer, Cham, p. 83-101.). In addition, the presence of weeds may compromise the final quality of agricultural products, contamination with their plant remains and seeds, or become alternative hosts of pests and diseases, multiplying them and becoming a source of inoculum for future reinfestation (Anwar et al. 2009ANWAR SS, ZIA A & JAVED N. 2009. Meloidogyne incognita infection of five weed genotypes. Pak J Zool 41(2): 95-100., Rich et al. 2009RICH JR, BRITO JA, KAUR R & FERRELL JA. 2009. Weed species as hosts of Meloidogyne: a review. Nematropica 36(2): 157-185., Singh et al. 2010SINGH SK, KHURMA UR & LOCKHART PJ. 2010. Weed host of root-knot nematodes and their distribution in Fiji. Weed Technology 24: 607-612., Bellé et al. 2017bBELLÉ C, KASPARY TE, KUHN PR, SCHMITT J & LIMA-MEDINA I. 2017a. Reproduction of Pratylenchus zeae on weeds. Planta Daninha 35: e017158528.). These factors, combining the broad geographic distribution, high capacity of production and propagation of propagules, and the constant evolution of herbicide-resistant genotypes, add to the importance of weeds as a biotic component to be managed in agricultural environments (Ramos et al. 2019RAMOS RF, KASPARY TE, BALARDIN RR, NORA DD, ANTONIOLI ZI & BELLÉ C. 2019. Plantas daninhas como hospedeiras dos nematoides-das-galhas. Revista Agronomia Brasileira 3(3): erab201906.).

The knowledge of weeds that act as alternative hosts of pests and diseases has been used as an integrated management tool in several agricultural crop systems. In this context, several weed species have been reported as plant-parasitic nematode hosts, among them root-knot nematodes (Meloidogyne spp.). This genus of phytoparasite has the greatest impact on crops in the world, besides being the most frequently found species parasitizing weed roots (Ferraz et al. 1978FERRAZ LCCB, PITELLI RA & FURLAN V. 1978. Nematóides associados a plantas daninhas na região de Jaboticabal, SP - primeiro relato. Planta Daninha 1: 5-11., Moens et al. 2009MOENS M, PERRY RN & STARR JL. 2009. Meloidogyne species – a diverse group of novel and important species. In: Root-Knot Nematodes. Wallingford: CABI, p. 1-17.). In Brazil, a growing number of studies on weeds in agricultural areas have been developed as natural hosts of several nematode species of the genus Meloidogyne (Bellé et al. 2016BELLÉ C, KASPARY TE, SCHMITT J & KUHN PR. 2016. Meloidogyne ethiopica and Meloidogyne arenaria parasitizing Oxalis corniculata in Brazil. Australas. Plant Dis Notes 11: 24., Groth et al. 2017GROTH, MZ, BELLÉ C, COCCO KLT, KASPARY TE, CASAROTTO G, CUTTI L & SCHMITT J. 2017. First report of Meloidogyne enterolobii infecting the weed jerusalem cherry (Solanum pseudocapsicum) in Brazil. Plant Dis 101(3): 510., Kaspary et al. 2017KASPARY TE, BELLÉ C, GROTH MZ, COCCO KLT, CUTTI L & CASAROTTO G. 2017. Amaranthus viridis is a weed host of Meloidogyne arenaria in Rio Grande do Sul State, Brazil. Plant Dis 101(4): 635.). The ability of several weeds to be susceptibility by M. incognita, M. javanica and M. paranaensis, and recently by M. enterolobii, are already described in the literature (Roese & Oliveira 2004ROESE AD & OLIVEIRA RDL. 2004. Capacidade reprodutiva de Meloidogyne paranaensis em espécies de plantas daninhas. Nematologia Brasileira 28(2): 137-141., Mônaco et al. 2008MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A, NAKAMURA, KC, MORITZ MP & SANTIAGO DC. 2008. Reação de espécies de plantas daninhas a Meloidogyne paranaensis. Nematologia Brasileira 32(4): 279-284., Bellé et al. 2017b). However, many other nematode species make up the genus Meloidogyne, and there is a lack of knowledge about their ability to parasite weeds, such is the case of M. morocciensis.

The first description of parasitism of the species M. morocciensis was carried out in the mid-90s on peach (Prunus persica L.) plants in Morocco (Rammah and Hirschmann 1990). In Central America M. morocciensis has been reported parasitizing coffee plants (Coffea arabica L.) in commercial plantations in Guatemala (Villain et al. 2013VILLAIN L, SARAH JL, HERNÁNDEZ A, BERTRAND B, ANTHONY F, LASHERMES P, CHARMETANT P, ANZUETO F & CARNEIRO RMDG. 2013. Diversity of root-knot nematodes parasitizing coffee in Central America. Nematropica 43(2): 194-206.). Meanwhile, in South America, this species has recently been reported parasitizing grapevine plants (Vitis vinifera L.) in the main table grape producing regions of Peru (Huaroto 2018HUAROTO NV. 2018. Caracterización de poblaciones peruanas del nematodo del nódulo de la raíz (Meloidogyne spp.) en vid (Vitis vinifera L.). Tesis. Perú: Universidad Nacional Agraria La Molina, 76 p., Pongo 2018PONGO JMA. 2018. Caracterización de poblaciones de nematodos del género Meloidogyne asociadas al cultivo de uva de mesa (Vitis vinifera L.) en las principales zonas productoras del norte del Perú. Tesis Perú: Universidad Nacional de Piura, 58 p. (Unpublished).). In Brazil, its presence is mainly associated with soybean (Glycine max L.) and grapevine cultivation in different regions of the country (Somavilla 2011SOMAVILLA L. 2011. Levantamento, caracterização do nematoide das galhas em videira nos estados do Rio Grande do Sul e de Santa Catarina e estudo da resistência de porta-enxertos a Meloidogyne spp. Tese de Doutorado. Brasil: Universidade Federal de Pelotas, 81 p., Kirsch et al. 2016KIRSCH VG, KULCZYNSKI SM, GOMES CB, BISOGNIN AC, GABRIEL M, BELLÉ C & LIMA-MEDINA I. 2016. Caracterização de espécies de Meloidogyne e de Helicotylenchus associadas à soja no Rio Grande do Sul. Nematropica 46(2): 197-208., Mattos et al. 2016MATTOS VS, FURLANETTO C, SILVA JGP, SANTOS DF, ALMEIDA MRA, CORREA VR, MOITA AW, CASTAGNONE-SERENO P & CARNEIRO RMDG. 2016. Meloidogyne spp. populations from native Cerrado and soybean cultivated areas: genetic variability and aggressiveness. Nematology 18(5): 1-11.). In addition, it shows reproduction in potato (Solanum tuberosum L.) (Lima-Medina et al. 2016LIMA-MEDINA I, BELLÉ C, CASA-COILA VH, PEREIRA AS & GOMES CB. 2016. Reação de cultivares de batata aos nematoides-das-galhas. Nematropica 46(2): 188-196.). Thus, this plant-parasitic nematode can be considered an emerging species in agriculture, which is little known about the potential range of host species.

In the current literature, there are no studies related to weed behavior as possible hosts of M. morocciensis. However, studies have shown that weeds are usually hosts of Meloidogyne genus nematodes (Anwar et al. 2009ANWAR SS, ZIA A & JAVED N. 2009. Meloidogyne incognita infection of five weed genotypes. Pak J Zool 41(2): 95-100., Mônaco et al. 2009MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242., Silva et al. 2013SILVA SLS, SANTOS TFS, RIBEIRO NR, SILVÉRIO AT & MORAIS TS. 2013. Reação de plantas daninhas a Meloidogyne incognita e M. javanica. Nematologia Brasileira 37(3-4): 57-60., Bellé et al. 2019BELLÉ C, RAMOS RF, BALLARDIN RR, KASPARY TE & ANTONIOLLI ZI. 2019. Reproduction of Meloidogyne enterolobii on different weeds. Trop Plant Pathol: 1-5.). Thus, the hypothesis of the present work is that M. morocciensis has the ability to parasite and reproduce in different species of weeds. Therefore, the objective of this study was to evaluate the reproduction of M. morocciensis in 36 weed species commonly found in agricultural areas of Brazil.

MATERIALS AND METHODS

The determination of M. morocciensis reproduction was performed using 36 weed species, commonly found in agricultural areas and belonging to 16 botanical families (Table I). The experiment was conducted from March to September 2018, in a greenhouse with a temperature set at 25 ± 3 °C. The experimental design was completely randomized, with twelve (12) replicates. Seeding of the weeds was started with seeds of lower speed of germination and development and finished with the fast development species. Thus, homogenization of development at inoculation was maintained. The substrate used in the experiment consisted of the mixture of sand and soil (2:1), which was sterilized by autoclaving. The soil used in the experiment is characterized as Latossolo Vermelho aluminoférrico, according to the Brazilian Soil Classification System (SBCS, 2013), with the following physical and chemical properties: clay = 48%; pH water = 6.5; SMP index = 6.5; potential acidity (H + Al) = 5.5 cmol_c.dm^-3; organic matter = 3.1%; sand = 30%; phosphorus = 10.9 mg.dm^-3; potassium = 88 mg.dm^-3; calcium = 5.3 cmol_c.dm^-3; magnesium = 5.0 cmol_c.dm^-3 and sulfur = 9 cmol_c.dm^-3. Ten days after emergence, the seedlings were transplanted into 2,000 dm³ pots containing substrate, one plant per pot.

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Table I
Family, scientific name, common name, habit, and distribution of weed species used in the present study.

The population of M. morocciensis (Est. A3) was isolated from soybean roots, from the Cerrito county, Rio Grande do Sul, Brazil (Kirsch et al. 2016KIRSCH VG, KULCZYNSKI SM, GOMES CB, BISOGNIN AC, GABRIEL M, BELLÉ C & LIMA-MEDINA I. 2016. Caracterização de espécies de Meloidogyne e de Helicotylenchus associadas à soja no Rio Grande do Sul. Nematropica 46(2): 197-208.), and multiplied in ‘Santa Cruz’ tomato. The nematode inoculum was obtained from the root system of plants kept in greenhouse, using the Hussey & Barker (1973)HUSSEY RS & BARKER KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Dis Rep 57: 1025-1028. method. The plants were inoculated five days after transplantation, with suspension of 5,000 eggs and second stage juveniles (J2), in three holes approximately 2 cm deep, open around the plant. ‘Santa Cruz’ tomatoes were used as standard to prove the viability of the inoculum used.

After 60 days of inoculation, the root systems were washed in running water and then the gall index (GI) was determined according to the methodology proposed by Taylor & Sasser (1978)TAYLOR AL & SASSER JN. 1978. Biology, identification and control of root-knot nematodes. North Carolina State University, Raleigh: Department of Plant Pathology., where 0 = no galls, 1 = 1 to 2, 2 = 3 to 10, 3 = 11 to 30, 4 = 31 to 100 and 5 = more than 100 galls per root system. Afterwards, the root systems were processed according to the method of Coolen & D’Herde (1972), using 0.5% sodium hypochlorite solution in substitution of water, for final nematode population (PF) quantification. From the final population of nematodes in the root system, calculations were performed for the number of nematode per root gram (NNGR) and reproduction factor (FR = final population / initial population) of M. morocciensis in each replicate. Immune (FR = 0), resistant (FR <1) and susceptible (FR> 1) species were considered (Oostenbrink 1966OOSTENBRINK M. 1966. Major characteristic of relation between nematodes and plants. Mededelingen Landbouwhogeschool 66(1): 1-46.). The number of nematodes per gram of root was estimated by the ratio of the total number of nematodes to the roots total mass, in grams, of each replicate.

The final nematode population data and the reproduction factor were submitted to analysis of variance, and the means were compared by the Scott-Knott test with a 95% confidence level using the GENES software (Cruz 2006CRUZ CD. 2006. Programa Genes – Estatística Experimental e Matrizes. 1ª ed., Viçosa: Editora UFV.).

RESULTS AND DISCUSSION

The differences in the living conditions indicates significant (p≤0.05%) in relation to M. morocciensis parasitism, based on the final population (PF), gall index (GI), number of nematodes per root gram (NNGR) and reproduction factor (RF), control (L. esculentus) (Table II). The viability of the nematode inoculum can be confirmed by the reproduction factor (FR = 51.6 ± 3.27) for the total control (Table II).

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Table II
Galls index (GI), final population (FP), nematodes per root gram (NNGR) and reproduction factors (RF) of Meloidogyne morocciensis on different weeds.

The data obtained in this work show that 77.8% (28) of the 36 weed species were susceptible (FR ≥ 1.0) to M. morocciensis, being: Acanthospermum australe (Loef) Kuntze, Amaranthus hybridus L., Amaranthus spinosus L., Amaranthus viridis L., Bidens pilosa L., Caperonia palustres (L.) A. St.-Hil., Cardiospermum halicacabum L., Chenopodium album L., Commelina benghalensis L., Cyperus rotundus L., Echinochloa colonum (L.) Link, Eleusine indica (L.) Gaertn, Euphorbia heterophylla L., Galinsoga parviflora Cav., Ipomoea grandifolia (Dammer) O’Donell, Ipomoea nil (L.) Roth., Ipomoea purpurea (L.) Roth., Leonurus sibiricus L., Nicandra physaloides (L.) Gaertn., Oxalis corniculata L., Polygonum hydropiperoides (Michx.) Small, Portulaca oleracea L., Sida rhombifolia L., Solanum americanum Mill., Solanum pseudocapsicum L., Solanum sisymbriifolium L., Sonchus oleraceus L. e Talinum paniculatum (Jacq.) Gaertn (Tabela 2). It was observed that 27.8% (10) of the weed species evaluated presented average GI values equal to the control (GI = 5 for L. esculentum). In this group, all species of the family Solanaceae (N. physaloides, S. americanum, S. pseudocapsicum and S. sisymbriifolium), in addition to the species A. viridis (Amaranthaceae), G. parviflora (Asteraceae), L. sibiricus (Lamiaceae), O. corniculata (Oxalidaceae) P. oleracea (Portulacaceae) and S. rhombifolia (Malvaceae).

The species O. corniculata and P. oleracea, in addition to presenting mean GI values equal to the control, resulted in the highest values for PF (> 76,000), NNGR (> 19,000) and RF (> 15) (Table II). From these results, these species can be considered excellent hosts of M. morocciensis, being options of parasitism of this nematode in orchard areas and in areas of annual crops, during the crop cycle or in off-season periods. In this sense, the host of M. morocciensis weeds represents the possibility of maintaining and increasing the nematode population in areas where these weeds are present, even in the absence of susceptible agricultural crops.

The weeds used in the present study may be hosts of other species of Meloidogyne. In Brazil, weeds O. corniculata, a perennial herbaceous plant that develops throughout Brazil, is reported as a susceptible of M. javanica and M. paranaenses (Mônaco et al. 2009MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242.), and has recently been reported as a host of M. ethiopica Whitehead and M. arenaria (Neal) Chitwood in southern Brazil (Bellé et al. 2016BELLÉ C, KASPARY TE, SCHMITT J & KUHN PR. 2016. Meloidogyne ethiopica and Meloidogyne arenaria parasitizing Oxalis corniculata in Brazil. Australas. Plant Dis Notes 11: 24.). The species P. oleracea, which is also found in all regions of Brazil, is considered susceptible to M. paranaensis (Monaco et al. 2008), and to M. enterolobii, for which it showed high susceptibility based on the presence of large numbers of nematodes per root gram (> 5084), IG (= 5) and FR (> 13) (Bellé et al. 2019BELLÉ C, RAMOS RF, BALLARDIN RR, KASPARY TE & ANTONIOLLI ZI. 2019. Reproduction of Meloidogyne enterolobii on different weeds. Trop Plant Pathol: 1-5.).

Considering the other weeds that have been shown susceptible to M. morocciensis in the present work, several of these species are also reported as susceptible to other plant-parasitic nematode species. In this sense, different weeds of the family Amaranthaceae are described as hosts to the root-knot nematodes in Brazil. Thus, the weed A. viridis, which in the present study had GI equal to the control (GI = 5), has been reported as a host of M. arenaria, M. incognita and M. enterolobii (Bellé et al. 2017b, 2019BELLÉ C, KULCZYNSKI, SM, KASPARY TE & KUHN PR. 2017b. Plantas daninhas como hospedeiras alternativas para Meloidogyne incognita. Nematropica 47(1): 26-33., Kaspary et al. 2017KASPARY TE, BELLÉ C, GROTH MZ, COCCO KLT, CUTTI L & CASAROTTO G. 2017. Amaranthus viridis is a weed host of Meloidogyne arenaria in Rio Grande do Sul State, Brazil. Plant Dis 101(4): 635.), as well as host of the lesion nematode Pratylenchus zeae Graham (Bellé et al. 2017a). While A. hybridus, considered one of the main invasive plant in agricultural crops in southern and southeastern Brazil, has been reported as susceptible of M. enterolobii, M. incognita, M. javanica, M. paranaensis, P. zeae and Pratylenchus brachyurus (Godfrey) (Souza et al. 2006SOUZA RM, NOGUEIRA MS, LIMA IM, MELARATO M & DOLINSKI CM. 2006. Manejo do nematoide das galhas da goiabeira em São João da Barra (RJ) e relato de novos hospedeiros. Nematologia Brasileira 30: 165-169., Mônaco et al. 2009MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242., Bellé et al. 2015BELLÉ C, LIMA-MEDINA, I, KASPARY TE & KUHN PR. 2015. Host suitability of weeds to Pratylenchus brachyurus in Northwest of Rio Grande do Sul, Brazil. Nematropica 45(2): 144-149., 2017a).

Weeds of the Solanaceae family, which behaved as susceptible to M. morocciensis, are widely distributed in Brazil, being recognized as important invasive plants in agricultural crops, besides being host of the plant-parasitic nematode genus Meloidogyne. In this context, S. sisymbriifolium and S. americanum are reported as susceptible of M. incognita, M. javanica and M. paranaensis (Mônaco et al. 2009MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242.); N. physaloides susceptible of M. incognita (Bellé et al. 2017b), while S. pseudocapsicum was recently reported as susceptible of M. enterolobii (Groth et al. 2017GROTH, MZ, BELLÉ C, COCCO KLT, KASPARY TE, CASAROTTO G, CUTTI L & SCHMITT J. 2017. First report of Meloidogyne enterolobii infecting the weed jerusalem cherry (Solanum pseudocapsicum) in Brazil. Plant Dis 101(3): 510.). Thus, the presence of weeds of this genus should be severely repressed in cultivated areas with crops susceptible to nematodes of the genus Meloidogyne, in order to avoid the multiplication and perpetuation of these pathogens and to reduce the negative impact on the crops.

The evaluation of 36 weed species revealed that only eight (22.2%) were classified as resistant (FR <1.0) to M. morocciensis and none as immune (FR = 0). The nematode resistant species were: Conyza bonariensis (L.), Cynodon dactylon (L.), Digitaria horizontalis Willd. (D), Digitaria insularis (L.), Lolium multiflorum (L), Raphanus raphanistrum L., Rhynchelytrum repens L. and Senecio brasiliensis (Spreng.) (Table II). In this group, five species belong to the botanical family Poaceae (C. dactylon, D. horizontalis, D. insularis, L. multiflorum and Rhynchelytrum repens), which presented low values for FR, ranging from 0.1 to 0.3 for the Digitaria spp. and C. dactylon, respectively.

The other species evaluated in the Poaceae family, although parasitized by M. morocciensis, also presented low values for the reproduction factor, with mean values of 1.3 and 4.3 for E. indica and E. colonum, respectively (Table II). These results indicate that this botanical family may present mechanisms of resistance to M. morocciensis, which may serve as a source of variability for breeding programs that seek genes of resistance to the Meloidogyne genus. The results of the present study corroborate those obtained by different studies that evaluated the susceptibility of weeds to other species of the genus Meloidogyne and which report D. insularis and R. repens as resistant to M. incognita, M. javanica and M. paranaenses (Mônaco et al. 2009MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242.). While D. horizontalis is described as resistant to M. incognita and M. javanica (Silva et al. 2013SILVA SLS, SANTOS TFS, RIBEIRO NR, SILVÉRIO AT & MORAIS TS. 2013. Reação de plantas daninhas a Meloidogyne incognita e M. javanica. Nematologia Brasileira 37(3-4): 57-60.). In addition, E. indica and L. multiflorum were resistant to M. incognita, whereas D. horizontalis, D. insularis and E. indica were resistant to M. enterolobii (Bellé et al. 2017b, 2019). These authors describe the resistance of Cyperus rotundus to M. enterolobii, while in the present work this species of the Cyperaceae family presents as susceptible to M. morocciensis (Table II)

The results obtained in the present work confirm the hypothesis that M. morocciensis is capable of parasitizing and reproducing in different weed species, from the reproduction observed in 36 different weeds belonging to 16 different botanical families. These results show that this pathogen species presents a polyphagous habit that, together with the broad geographic distribution of most weed species in several crops, can facilitate its dissemination in Brazilian agricultural areas.

The abundance (synonymous of population density) of a weed species and the reproduction factor of the nematodes in this species determines the magnitude of the effect that the weed has on the population densities of the nematodes (Anwar et al. 2009ANWAR SS, ZIA A & JAVED N. 2009. Meloidogyne incognita infection of five weed genotypes. Pak J Zool 41(2): 95-100.). Thus, the weed species that commonly present high population density in the growing areas and are excellent hosts of Meloidogyne sp., are those with the greatest potential to maintain and raise the populations of these plant-parasitic nematodes in cultivated areas. In this sense, weeds with greater potential for multiplication and all those with a hostability of these pathogens increase their capacity to cause damage to crop and should be considered priorities in integrated management programs in areas of occurrence of root-knot nematode.

REFERENCES

ANWAR SS, ZIA A & JAVED N. 2009. Meloidogyne incognita infection of five weed genotypes. Pak J Zool 41(2): 95-100.
BELLÉ C, KASPARY TE, KUHN PR, SCHMITT J & LIMA-MEDINA I. 2017a. Reproduction of Pratylenchus zeae on weeds. Planta Daninha 35: e017158528.
BELLÉ C, KASPARY TE, SCHMITT J & KUHN PR. 2016. Meloidogyne ethiopica and Meloidogyne arenaria parasitizing Oxalis corniculata in Brazil. Australas. Plant Dis Notes 11: 24.
BELLÉ C, KULCZYNSKI, SM, KASPARY TE & KUHN PR. 2017b. Plantas daninhas como hospedeiras alternativas para Meloidogyne incognita. Nematropica 47(1): 26-33.
BELLÉ C, RAMOS RF, BALLARDIN RR, KASPARY TE & ANTONIOLLI ZI. 2019. Reproduction of Meloidogyne enterolobii on different weeds. Trop Plant Pathol: 1-5.
BELLÉ C, LIMA-MEDINA, I, KASPARY TE & KUHN PR. 2015. Host suitability of weeds to Pratylenchus brachyurus in Northwest of Rio Grande do Sul, Brazil. Nematropica 45(2): 144-149.
COOLEN WA & D’ HERDE CJ. 1972. A method for quantitative extraction of nematodes from plant tissue. In: State Nematology end Entomology Research Station, Ghent, 77 p.
CRUZ CD. 2006. Programa Genes – Estatística Experimental e Matrizes. 1ª ed., Viçosa: Editora UFV.
FERRAZ LCCB, PITELLI RA & FURLAN V. 1978. Nematóides associados a plantas daninhas na região de Jaboticabal, SP - primeiro relato. Planta Daninha 1: 5-11.
FLORARS - FLORA DIGITAL DO RIO GRANDE DO SUL E DE SANTA CATARINA. 2019. Available on line: http://www.ufrgs.br/fitoecologia/florars/index.php
» http://www.ufrgs.br/fitoecologia/florars/index.php
FRIED G, CHAUVEL B, REYNAUD P & SACHE I. 2017. Decreases in Crop Production by Non-native Weeds, Pests, and Pathogens. In: Impact of Biological Invasions on Ecosystem Services, 12. Invading Nature - Springer Series in Invasion Ecology, vol 12. Springer, Cham, p. 83-101.
GAZZIERO DLP, LOLLATO RP, BRIGHENTI AM, PITELLI RA & VOLL E. 2015. Manual de identificação de plantas daninhas da cultura da soja. 2ª ed. Londrina: Embrapa Soja, 126 p.
GROTH, MZ, BELLÉ C, COCCO KLT, KASPARY TE, CASAROTTO G, CUTTI L & SCHMITT J. 2017. First report of Meloidogyne enterolobii infecting the weed jerusalem cherry (Solanum pseudocapsicum) in Brazil. Plant Dis 101(3): 510.
HUAROTO NV. 2018. Caracterización de poblaciones peruanas del nematodo del nódulo de la raíz (Meloidogyne spp.) en vid (Vitis vinifera L.). Tesis. Perú: Universidad Nacional Agraria La Molina, 76 p.
HUSSEY RS & BARKER KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Dis Rep 57: 1025-1028.
KASPARY TE, BELLÉ C, GROTH MZ, COCCO KLT, CUTTI L & CASAROTTO G. 2017. Amaranthus viridis is a weed host of Meloidogyne arenaria in Rio Grande do Sul State, Brazil. Plant Dis 101(4): 635.
KIRSCH VG, KULCZYNSKI SM, GOMES CB, BISOGNIN AC, GABRIEL M, BELLÉ C & LIMA-MEDINA I. 2016. Caracterização de espécies de Meloidogyne e de Helicotylenchus associadas à soja no Rio Grande do Sul. Nematropica 46(2): 197-208.
LIMA-MEDINA I, BELLÉ C, CASA-COILA VH, PEREIRA AS & GOMES CB. 2016. Reação de cultivares de batata aos nematoides-das-galhas. Nematropica 46(2): 188-196.
MATTOS VS, FURLANETTO C, SILVA JGP, SANTOS DF, ALMEIDA MRA, CORREA VR, MOITA AW, CASTAGNONE-SERENO P & CARNEIRO RMDG. 2016. Meloidogyne spp. populations from native Cerrado and soybean cultivated areas: genetic variability and aggressiveness. Nematology 18(5): 1-11.
MOENS M, PERRY RN & STARR JL. 2009. Meloidogyne species – a diverse group of novel and important species. In: Root-Knot Nematodes. Wallingford: CABI, p. 1-17.
MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A, NAKAMURA, KC, MORITZ MP & SANTIAGO DC. 2008. Reação de espécies de plantas daninhas a Meloidogyne paranaensis. Nematologia Brasileira 32(4): 279-284.
MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242.
MOREIRA HJC & BRAGANÇA HBN. 2011. Manual de identificação de plantas infestantes: Hortifrúti. São Paulo: FMC Agricultural Products, 1017 p.
OOSTENBRINK M. 1966. Major characteristic of relation between nematodes and plants. Mededelingen Landbouwhogeschool 66(1): 1-46.
PONGO JMA. 2018. Caracterización de poblaciones de nematodos del género Meloidogyne asociadas al cultivo de uva de mesa (Vitis vinifera L.) en las principales zonas productoras del norte del Perú. Tesis Perú: Universidad Nacional de Piura, 58 p. (Unpublished).
RAMOS RF, KASPARY TE, BALARDIN RR, NORA DD, ANTONIOLI ZI & BELLÉ C. 2019. Plantas daninhas como hospedeiras dos nematoides-das-galhas. Revista Agronomia Brasileira 3(3): erab201906.
RAMMAH A & HIRSCHMANN H. 1990. Meloidogyne morocciensis n. sp. (Meloidogyninae), a root-knot nematode from Morocco. J. Nematol. 22(3): 279-291.
RICH JR, BRITO JA, KAUR R & FERRELL JA. 2009. Weed species as hosts of Meloidogyne: a review. Nematropica 36(2): 157-185.
ROESE AD & OLIVEIRA RDL. 2004. Capacidade reprodutiva de Meloidogyne paranaensis em espécies de plantas daninhas. Nematologia Brasileira 28(2): 137-141.
SBCS - SISTEMA BRASILEIRA DE CLASSIFICAÇÃO DE SOLOS. 2013. 3ª ed., Brasília, DF: Embrapa, 353 p.
SILVA SLS, SANTOS TFS, RIBEIRO NR, SILVÉRIO AT & MORAIS TS. 2013. Reação de plantas daninhas a Meloidogyne incognita e M. javanica. Nematologia Brasileira 37(3-4): 57-60.
SINGH SK, KHURMA UR & LOCKHART PJ. 2010. Weed host of root-knot nematodes and their distribution in Fiji. Weed Technology 24: 607-612.
SOMAVILLA L. 2011. Levantamento, caracterização do nematoide das galhas em videira nos estados do Rio Grande do Sul e de Santa Catarina e estudo da resistência de porta-enxertos a Meloidogyne spp. Tese de Doutorado. Brasil: Universidade Federal de Pelotas, 81 p.
SOUZA RM, NOGUEIRA MS, LIMA IM, MELARATO M & DOLINSKI CM. 2006. Manejo do nematoide das galhas da goiabeira em São João da Barra (RJ) e relato de novos hospedeiros. Nematologia Brasileira 30: 165-169.
TAYLOR AL & SASSER JN. 1978. Biology, identification and control of root-knot nematodes. North Carolina State University, Raleigh: Department of Plant Pathology.
VILLAIN L, SARAH JL, HERNÁNDEZ A, BERTRAND B, ANTHONY F, LASHERMES P, CHARMETANT P, ANZUETO F & CARNEIRO RMDG. 2013. Diversity of root-knot nematodes parasitizing coffee in Central America. Nematropica 43(2): 194-206.

Publication Dates

Publication in this collection
04 Dec 2023
Date of issue
2023

History

Received
1 Apr 2019
Accepted
20 June 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ANWAR SS, ZIA A & JAVED N. 2009. Meloidogyne incognita infection of five weed genotypes. Pak J Zool 41(2): 95-100.

[2] BELLÉ C, KASPARY TE, KUHN PR, SCHMITT J & LIMA-MEDINA I. 2017a. Reproduction of Pratylenchus zeae on weeds. Planta Daninha 35: e017158528.

[3] BELLÉ C, KASPARY TE, SCHMITT J & KUHN PR. 2016. Meloidogyne ethiopica and Meloidogyne arenaria parasitizing Oxalis corniculata in Brazil. Australas. Plant Dis Notes 11: 24.

[4] BELLÉ C, KULCZYNSKI, SM, KASPARY TE & KUHN PR. 2017b. Plantas daninhas como hospedeiras alternativas para Meloidogyne incognita. Nematropica 47(1): 26-33.

[5] BELLÉ C, RAMOS RF, BALLARDIN RR, KASPARY TE & ANTONIOLLI ZI. 2019. Reproduction of Meloidogyne enterolobii on different weeds. Trop Plant Pathol: 1-5.

[6] BELLÉ C, LIMA-MEDINA, I, KASPARY TE & KUHN PR. 2015. Host suitability of weeds to Pratylenchus brachyurus in Northwest of Rio Grande do Sul, Brazil. Nematropica 45(2): 144-149.

[7] COOLEN WA & D’ HERDE CJ. 1972. A method for quantitative extraction of nematodes from plant tissue. In: State Nematology end Entomology Research Station, Ghent, 77 p.

[8] CRUZ CD. 2006. Programa Genes – Estatística Experimental e Matrizes. 1ª ed., Viçosa: Editora UFV.

[9] FERRAZ LCCB, PITELLI RA & FURLAN V. 1978. Nematóides associados a plantas daninhas na região de Jaboticabal, SP - primeiro relato. Planta Daninha 1: 5-11.

[10] FLORARS - FLORA DIGITAL DO RIO GRANDE DO SUL E DE SANTA CATARINA. 2019. Available on line: http://www.ufrgs.br/fitoecologia/florars/index.php
» http://www.ufrgs.br/fitoecologia/florars/index.php

[11] FRIED G, CHAUVEL B, REYNAUD P & SACHE I. 2017. Decreases in Crop Production by Non-native Weeds, Pests, and Pathogens. In: Impact of Biological Invasions on Ecosystem Services, 12. Invading Nature - Springer Series in Invasion Ecology, vol 12. Springer, Cham, p. 83-101.

[12] GAZZIERO DLP, LOLLATO RP, BRIGHENTI AM, PITELLI RA & VOLL E. 2015. Manual de identificação de plantas daninhas da cultura da soja. 2ª ed. Londrina: Embrapa Soja, 126 p.

[13] GROTH, MZ, BELLÉ C, COCCO KLT, KASPARY TE, CASAROTTO G, CUTTI L & SCHMITT J. 2017. First report of Meloidogyne enterolobii infecting the weed jerusalem cherry (Solanum pseudocapsicum) in Brazil. Plant Dis 101(3): 510.

[14] HUAROTO NV. 2018. Caracterización de poblaciones peruanas del nematodo del nódulo de la raíz (Meloidogyne spp.) en vid (Vitis vinifera L.). Tesis. Perú: Universidad Nacional Agraria La Molina, 76 p.

[15] HUSSEY RS & BARKER KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Dis Rep 57: 1025-1028.

[16] KASPARY TE, BELLÉ C, GROTH MZ, COCCO KLT, CUTTI L & CASAROTTO G. 2017. Amaranthus viridis is a weed host of Meloidogyne arenaria in Rio Grande do Sul State, Brazil. Plant Dis 101(4): 635.

[17] KIRSCH VG, KULCZYNSKI SM, GOMES CB, BISOGNIN AC, GABRIEL M, BELLÉ C & LIMA-MEDINA I. 2016. Caracterização de espécies de Meloidogyne e de Helicotylenchus associadas à soja no Rio Grande do Sul. Nematropica 46(2): 197-208.

[18] LIMA-MEDINA I, BELLÉ C, CASA-COILA VH, PEREIRA AS & GOMES CB. 2016. Reação de cultivares de batata aos nematoides-das-galhas. Nematropica 46(2): 188-196.

[19] MATTOS VS, FURLANETTO C, SILVA JGP, SANTOS DF, ALMEIDA MRA, CORREA VR, MOITA AW, CASTAGNONE-SERENO P & CARNEIRO RMDG. 2016. Meloidogyne spp. populations from native Cerrado and soybean cultivated areas: genetic variability and aggressiveness. Nematology 18(5): 1-11.

[20] MOENS M, PERRY RN & STARR JL. 2009. Meloidogyne species – a diverse group of novel and important species. In: Root-Knot Nematodes. Wallingford: CABI, p. 1-17.

[21] MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A, NAKAMURA, KC, MORITZ MP & SANTIAGO DC. 2008. Reação de espécies de plantas daninhas a Meloidogyne paranaensis. Nematologia Brasileira 32(4): 279-284.

[22] MÔNACO APA, CARNEIRO RG, KRANZ WM, GOMES JC, SCHERER A & SANTIAGO DC. 2009. Reação de espécies de plantas daninhas a Meloidogyne incognita Raças 1 e 3, a M. javanica e a M. paranaenses. Nematologia Brasileira 33(3): 235-242.

[23] MOREIRA HJC & BRAGANÇA HBN. 2011. Manual de identificação de plantas infestantes: Hortifrúti. São Paulo: FMC Agricultural Products, 1017 p.

[24] OOSTENBRINK M. 1966. Major characteristic of relation between nematodes and plants. Mededelingen Landbouwhogeschool 66(1): 1-46.

[25] PONGO JMA. 2018. Caracterización de poblaciones de nematodos del género Meloidogyne asociadas al cultivo de uva de mesa (Vitis vinifera L.) en las principales zonas productoras del norte del Perú. Tesis Perú: Universidad Nacional de Piura, 58 p. (Unpublished).

[26] RAMOS RF, KASPARY TE, BALARDIN RR, NORA DD, ANTONIOLI ZI & BELLÉ C. 2019. Plantas daninhas como hospedeiras dos nematoides-das-galhas. Revista Agronomia Brasileira 3(3): erab201906.

[27] RAMMAH A & HIRSCHMANN H. 1990. Meloidogyne morocciensis n. sp. (Meloidogyninae), a root-knot nematode from Morocco. J. Nematol. 22(3): 279-291.

[28] RICH JR, BRITO JA, KAUR R & FERRELL JA. 2009. Weed species as hosts of Meloidogyne: a review. Nematropica 36(2): 157-185.

[29] ROESE AD & OLIVEIRA RDL. 2004. Capacidade reprodutiva de Meloidogyne paranaensis em espécies de plantas daninhas. Nematologia Brasileira 28(2): 137-141.

[30] SBCS - SISTEMA BRASILEIRA DE CLASSIFICAÇÃO DE SOLOS. 2013. 3ª ed., Brasília, DF: Embrapa, 353 p.

[31] SILVA SLS, SANTOS TFS, RIBEIRO NR, SILVÉRIO AT & MORAIS TS. 2013. Reação de plantas daninhas a Meloidogyne incognita e M. javanica. Nematologia Brasileira 37(3-4): 57-60.

[32] SINGH SK, KHURMA UR & LOCKHART PJ. 2010. Weed host of root-knot nematodes and their distribution in Fiji. Weed Technology 24: 607-612.

[33] SOMAVILLA L. 2011. Levantamento, caracterização do nematoide das galhas em videira nos estados do Rio Grande do Sul e de Santa Catarina e estudo da resistência de porta-enxertos a Meloidogyne spp. Tese de Doutorado. Brasil: Universidade Federal de Pelotas, 81 p.

[34] SOUZA RM, NOGUEIRA MS, LIMA IM, MELARATO M & DOLINSKI CM. 2006. Manejo do nematoide das galhas da goiabeira em São João da Barra (RJ) e relato de novos hospedeiros. Nematologia Brasileira 30: 165-169.

[35] TAYLOR AL & SASSER JN. 1978. Biology, identification and control of root-knot nematodes. North Carolina State University, Raleigh: Department of Plant Pathology.

[36] VILLAIN L, SARAH JL, HERNÁNDEZ A, BERTRAND B, ANTHONY F, LASHERMES P, CHARMETANT P, ANZUETO F & CARNEIRO RMDG. 2013. Diversity of root-knot nematodes parasitizing coffee in Central America. Nematropica 43(2): 194-206.

Family	Scientific name	Common name ^a	Habit ^b	Distribution regions ^a , ^b
Amaranthaceae	Amaranthus hybridus L.	Slim amaranth	HA³	Southeast and South
	Amaranthus spinosus L.	Spiny amaranth	HA	All regions
	Amaranthus viridis L.	Green amaranth	HA	All regions
	Chenopodium album L.	White goosefoot	HA	Midwest, Southeast and South
Asteraceae	Acanthospermum australe (Loefl.) Kuntze	Paraguay starburr	HA	All regions
	Bidens pilosa (L.) DC.	Hairy beggarticks	HA	All regions
	Conyza bonariensis (L.) Cronquist	Hairy fleabane	HA	All regions
	Galinsoga parviflora Cav.	Gallant soldier	HA	Southeast and South
	Senecio brasiliensis (Spreng.) Less.	Flower-of-souls	SP	Midwest,Southeast and South
	Sonchus oleraceus L.	Common sowthistle	HA/HB	All regions
Brassicaceae	Raphanus raphanistrum L.	Wild radish	HA	Midwest, Southeast and Soouth
Commelinaceae	Commelina benghalensis L.	Benghal dayflower	HP	All regions
Convolvulaceae	Ipomoea grandifolia (Dammer) O’Donell	Morning glory	TA	All regions
	Ipomoea nil (L.) Roth.	Morning glory	HA	All regions
	Ipomoea purpurea (L.) Roth.	Morning glory	HA	All regions
Cyperaceae	Cyperus rotundus L.	Nutgrass	HP	All regions
Euphorbiaceae	Caperonia palustris (L.) A. St.-Hil.	Sacatrapo	HA	North, Northeast, Midwest and Southeast
	Euphorbia heterophylla L.	Fireplant	HA	All regions
Lamiaceae	Leonurus sibiricus L.	Honeyweed	HA/HB	All regions
Malvaceae	Sida rhombifolia L.	Arrowleaf sida	SP	All regions
Oxalidaceae	Oxalis corniculata L.	Creeping woodsorrel	HP	All regions
Poaceae	Cynodon dactylon (L.) Pers.	Bermuda grass	PHP	All regions
	Digitaria horizontalis Willd. (Digho)	Crabgrass; Sourgrass	GAE	All regions
	Digitaria insularis (L.) Fedde	Sourgrass	GAE	All regions
	Echinochloa colonum (L.) Link	Jungle rice	GAE	All regions
	Eleusine indica (L.) Gaertn	Indian goosegrass	GAE	All regions
	Lolium multiflorum Lam.	Ryegrass	GAE/GBA	Southeast and South
	Rhynchelytrum repens (Willd.) C.E.Hubb	Natal grass	GAE	All regions
Polygonaceae	Polygonum hydropiperoides (Michx.) Small	Swamp smartweed	HP	Midwest, Southeast, South and Bahia State
Portulacaceae	Portulaca oleracea L.	Verdolaga; Red root	HA	All regions
Sapindaceae	Cardiospermum halicacabum L.	Balloon vine	TA	All regions
Solanaceae	Nicandra physaloides (L.) Gaertn.	Apple-of-Peru	AS	All regions
	Solanum americanum Mill.	American black nightshade	HA	All regions
	Solanum pseudocapsicum L.	Jerusalem cherry	AP/SP	Midwest, Southeast and South.
	Solanum sisymbriifolium Lam.	Sticky nightshade	HP/SP	Midwest, Southeast, South and Bahia State
Talinaceae	Talinum paniculatum (Jacq.) Gaertn	Fameflower	HA	All regions

Species	GI ^a		PF ^b		NNGR ^c		FR ^d		Reaction ^e
Acanthospermum australe	2.0 ± 0.21 ^f	F	5417 ± 368	H	1316 ± 102	F	1.1 ± 0.07	H	S
Amaranthus hybridus	4.7 ± 0.14	B	18375 ± 1360	G	4412 ± 321	E	3.7 ± 0.27	G	S
Amaranthus spinosus	3.7 ± 0.14	C	36750 ± 3182	E	8430 ± 943	D	7.4 ± 0.64	E	S
Amaranthus viridis	5.0 ± 0.00	A	24792 ± 2831	F	5792 ± 637	E	5.0 ± 0.57	F	S
Bidens pilosa	4.1 ± 0.15	C	11667 ± 1236	H	3045 ± 336	F	2.3 ± 0.25	H	S
Caperonia palustres	4.5 ± 0.15	B	36375 ± 4128	E	8253 ± 940	D	7.3 ± 0.83	E	S
Cardiospermum halicacabum	3.9 ± 0.23	C	22667 ± 2882	F	5600 ± 867	E	4.5 ± 0.58	F	S
Chenopodium album	3.6 ± 0.15	C	62750 ± 3528	C	14815 ± 624	B	12.6 ± 0.71	C	S
Commelina benghalensis	3.3 ± 0.13	D	10042 ± 1072	H	2247 ± 278	F	2.0 ± 0.21	H	S
Conyza bonariensis	0.4 ± 0.15	I	796 ± 171	I	201 ± 55	G	0.2 ± 0.03	I	R
Cynodon dactylon	1.0 ± 0.17	H	1625 ± 247	I	415 ± 68	G	0.3 ± 0.05	I	R
Cyperus rotundus	3.0 ± 0.21	D	9083 ± 931	H	2322 ± 253	F	1.8 ± 0.19	H	S
Digitaria horizontalis	1.5 ± 0.26	G	479 ± 102	I	109 ± 25	G	0.1 ± 0.02	I	R
Digitaria insularis	1.6 ± 0.15	G	621 ± 119	I	160 ± 37	G	0.1 ± 0.02	I	R
Echinochloa colonum	2.5 ± 0.26	E	21708 ± 1498	F	5461 ± 416	E	4.3 ± 0.30	F	S
Eleusine indica	2.7 ± 0.22	E	6542 ± 675	H	1702 ± 169	F	1.3 ± 0.14	H	S
Euphorbia heterophylla	3.8 ± 0.21	C	19917 ± 2023	G	4420 ± 469	E	4.0 ± 0.40	G	S
Galinsoga parviflora	5.0 ± 0.00	A	46042 ± 2216	D	11023 ± 695	C	9.2 ± 0.44	D	S
Ipomoea grandifolia	4.3 ± 0.14	B	26833 ± 2397	F	6684 ± 581	D	5.4 ± 0.48	F	S
Ipomoea nil	4.0 ± 0.17	C	23458 ± 3976	F	5719 ± 954	E	4.7 ± 0.80	F	S
Ipomoea purpurea	4.3 ± 0.19	B	24458 ± 3700	F	5663 ± 835	E	4.9 ± 0.74	F	S
Leonurus sibiricus	5.0 ± 0.00	A	19667 ± 2735	G	4773 ± 697	E	3.9 ± 0.55	G	S
Lolium multiflorum	0.3 ± 0.19	I	946 ± 167	I	237 ± 33	G	0.2 ± 0.03	I	R
Nicandra physaloides	5.0 ± 0.00	A	15250 ± 1572	G	3841 ± 387	E	3.1 ± 0.31	G	S
Oxalis corniculata	5.0 ± 0.00	A	91208 ± 3289	A	21324 ± 924	A	18.2 ± 0.66	A	S
Polygonum hydropiperoides	1.1 ± 0.23	H	7813 ± 685	H	1909 ± 207	F	1.6 ± 0.14	H	S
Portulaca oleracea	5.0 ± 0.00	A	76833 ± 3584	B	19856 ± 1329	A	15.4 ± 0.72	B	S
Raphanus raphanistrum	2.1 ± 0.19	F	1792 ± 226	I	464 ± 74	G	0.4 ± 0.05	I	R
Rhynchelytrum repens	1.3 ± 0.14	G	1229 ± 155	I	299 ± 42	G	0.2 ± 0.03	I	R
Senecio brasiliensis	1.4 ± 0.15	G	942 ± 182	I	251 ± 56	G	0.2 ± 0.04	I	R
Sida rhombifolia	5.0 ± 0.00	A	50292 ± 5508	D	13706 ± 1730	B	10.1 ± 1.10	D	S
Solanum americanum	5.0 ± 0.00	A	19042 ± 1701	G	4580 ± 548	E	3.8 ± 0.34	G	S
Solanum pseudocapsicum	5.0 ± 0.00	A	24417 ± 2193	F	5666 ± 647	E	4.9 ± 0.44	F	S
Solanum sisymbriifolium	5.0 ± 0.00	A	32542 ± 3420	E	8274 ± 964	D	6.5 ± 0.68	E	S
Sonchus oleraceus	0.9 ± 0.19	H	5167 ± 4671	H	1229 ± 1094	F	1.0 ± 0.93	H	S
Talinum paniculatum	4.8 ± 0.11	A	30583 ± 3027	E	8339 ± 878	D	6.1 ± 0.61	E	S
Lycopersicum esculentum	5.0 ± 0.00	-	258083 ± 16334	-	6000 ± 442	-	51.6 ± 3.27	-	-
CV (%)	16.09		39.42		43.81		39.42

Brasil